Original Article

Superficial and Deep Foveal Avascular Zone Area
Measurement in Healthy Subjects Using Two Different

Spectral Domain Optical Coherence Tomography
Angiography Devices

Pasha Anvari, MD MPH; Amin Najafi, MD; Reza Mirshahi, MD; Mahsa Sardarinia, MD
Maryam Ashrafkhorasani, MD; Pegah Kazemi, BS; Gholamhoseyn Aghai, MD; Abbas Habibi, MD

Khalil Ghasemi Falavarjani, MD

Eye Research Center, The Five Senses Institute, Rassoul Akram Hospital, Iran University of Medical Sciences, Tehran, Iran

ORCID:
Pasha Anvari: https://orcid.org/0000-0002-3765-4206

Khalil Ghasemi Falavarjani: https://orcid.org/0000-0001-5221-1844

Abstract
Purpose: To compare the area of the foveal avascular zone (FAZ) in the superficial and deep
retinal layers using two different spectral-domain optical coherence tomography angiography
(OCTA) devices.
Methods: A cross-sectional comparative study was conducted to obtain macular OCTA images
from healthy subjects using Optovue RTVue XR Avanti (Optovue, Inc, Fremont, CA) and Spectralis
HRA+OCTA (Heidelberg Engineering, Heidelberg, Germany). Two independent trained graders
measured the FAZ area using automated slab segmentation. The FAZ area in the superficial and
deep retinal layers were compared.
Results: Twenty-three eyes of 23 subjects were included. The graders agreement was excellent
(>0.86) for all measurements. The mean FAZ area was significantly larger at the superficial retinal
layer as compared to the deep retinal layer on both devices (0.31 ± 0.08 mm2 vs 0.26 ± 0.08 mm2
in Optovue and 0.55 ± 0.16 mm2 vs 0.36 ± 0.13 mm2 in Spectralis, both P < 0.001). The mean
FAZ area was significantly greater in the superficial and deep retinal layers using Spectralis as
compared to Optovue measurements (P < 0.001 for both comparisons).
Conclusion: In contrast to previous reports, the FAZ area was larger in the superficial retina as
compared to deep retinal layers using updated software versions. Measurements from different
devices cannot be used interchangeably.

Keywords: Fovea Avascular Zone; Optical Coherence Tomography Angiography; Optovue; Spectral-
domain; Spectralis

J Ophthalmic Vis Res 2020; 15 (4): 517–523

Correspondence to:

Khalil Ghasemi Falavarjani, MD. Eye Research Center,
Rassoul Akram Hospital, Sattarkhan-Niaiesh St., Tehran,
Iran.
Email: drghasemi@yahoo.com
ghasemifalavarjani.k@iums.ac.ir
Received: 25-02-2020 Accepted: 20-07-2020

Access this article online

Website:
https://knepublishing.com/index.php/JOVR

DOI:
10.18502/jovr.v15i4.7791

INTRODUCTION

Foveal avascular zone (FAZ) is the vessel-free
central part of the macula surrounded by a

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How to cite this article: Anvari P, Najafi A, Mirshahi R, Sardarinia M,
Ashrafkhorasani M, Kazemi P, Aghai G, Habibi A, Falavarjani KG. Superficial
and Deep Foveal Avascular Zone Area Measurement in Healthy Subjects
Using Two Different Spectral Domain Optical Coherence Tomography
Angiography Devices. J Ophthalmic Vis Res 2020;15:517–523.

© 2020 JOURNAL OF OPHTHALMIC AND VISION RESEARCH | PUBLISHED BY KNOWLEDGE E 517

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Fovea Avascular Zone in Two OCTA Devices; Anvari et al

continuous network of capillary plexus. FAZ
integrity is vital for normal visual acuity. Some
retinal pathologies including retinal vascular
occlusions and diabetic retinopathy alter FAZ
shape; therefore, FAZ metrics can serve as
prognostic biomarkers for visual acuity.[1–5] Prior
to the advent of optical coherence tomography
angiography (OCTA), the most extensively used
tools for evaluation of FAZ were fluorescein
angiography (FA) and indocyanine green
angiography (ICGA).[6–8] However, FA and ICGA are
invasive procedures with side effects associated
with intravenous administration of the dye.[9] In
addition, dye leakage from incompetent vessels
may fade FAZ border in retinal pathologies,
complicating FAZ assessment. OCTA is a non-
invasive modality to evaluate retinal and choroidal
vasculature that generates flow maps of retinal
vasculature through discrimination of blood motion
signals.[10–13]

Multiple OCTA devices are commercially
available with distinct built-in software, algorithms,
and techniques for visualization of retinal and
choroidal vasculature and layer segmentation. The
reliability and reproducibility of images provided
by each device and the inter-device correlations
are of great importance in clinical decision-making
and patients’ follow-up.[14] Although several studies
have reported the size of FAZ in OCTA images,
automated segmentations of retinal slabs in older
versions has remained a source of measurement
error.[15, 16]

The aim of this study was to measure and
compare the FAZ area at the superficial and deep
retinal layers using two different OCTA devices with
the updated software versions.

METHODS

This cross-sectional comparative case-series was
approved by the Iran University Ethics Committee
(No. IR.IUMS.REC 1396.32837). Informed consent
was obtained and the tenets of the Declaration of
Helsinki were followed.

In total 23 eyes of 23 healthy employees of
Rassoul Akram Hospital, without any medical
conditions or ocular abnormalities, were enrolled
between June 2018 and December 2018. All
volunteers underwent a complete ophthalmic
examination including best-corrected visual
acuity (BCVA), slit-lamp examination, and fundus

examination. Subjects with abnormal or suspicious
findings during the examination were excluded.
The right eye was considered as the target eye for
OCTA imaging. All images were obtained on the
same day, between 8 am and 11 am.

OCTA images were obtained using the Optovue
RTVue XR Avanti (3 × 3 mm centered on the
fovea, Software version 2017.1.0.15, Optovue, Inc.,
Fremont, CA) and Spectralis HRA+OCTA (15° ×
10° scan pattern, Software version 6.9, 2017,
Heidelberg Engineering, Heidelberg, Germany).
The Optovue device visualizes retinal vasculature
using a split-spectrum amplitude decorrelation
algorithm (SSADA). The Spectralis is based on
a probability algorithm which determines the
presence of motion in each pixel by full spectrum
amplitude-decorrelation.[17]

For Optovue, images with a quality score of
<5 were excluded, and imaging was repeated
until acceptable quality was achieved. The
superficial capillary plexus (SCP) en face image was
segmented automatically with an inner boundary
set at the internal limiting membrane (ILM) and an
outer boundary set 9 µm above the inner plexiform
layer (IPL). The deep capillary plexus (DCP) en face
image was segmented with an inner boundary 9
µm above the IPL and an outer boundary at 9 µm
below the outer plexiform layer (OPL).

In the Spectralis device, only images with
Q scores greater than 15 were included. The
superficial vascular complex (SVC) was segmented
automatically from ILM to 17 µm above the bottom
border of the IPL and the deep vascular complex
(DVC) was bounded from 17 µm above the lower
border of the IPL to the bottom of the outer
plexiform layer. OCTA images were imported into
ImageJ software (public domain software, National
Institutes of Health, Bethesda, Maryland, USA).
The measurement scale was calibrated using the
known dimensions of the image (3 × 3 mm for
Optovue and 200 microns scale bar for Spectralis)
and the FAZ boundary was outlined manually
using freehand selection tools by two independent
trained graders (PA and MS) in the superficial, deep,
and the full retinal slabs.

Statistical data analysis was performed using the
SPSS (version 17.0; SPSS Inc., Chicago, IL, USA).
Intra-class correlation coefficient (ICC) between
graders was calculated. The Shapiro–Wilk test was
used to verify the normality of data. Paired t-test
was used to compare mean values between two

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Fovea Avascular Zone in Two OCTA Devices; Anvari et al

devices. The Bland–Altman plot was employed to
assess the agreement between the two devices in
measuring the FAZ area at different retinal layers.
P-values < 0.05 were considered significant.

RESULTS

Twenty-three eyes of 23 normal subjects including
14 females (60.9%) and 9 males (39.1%) with a
mean age of 34.2 ± 8.7 (range 28–59) years
were included. ICC was 0.87, 0.88, and 0.86 for
the measurements at superficial, deep, and full
retina slabs with the Optovue device and 0.92,
0.86, and 0.88 for the measurements with the
Spectralis device, respectively. In view of the
excellent agreement between the graders, the
mean values for the two graders were used for
subsequent analysis.

Table 1 compares the FAZ measurements at the
superficial and deep retinal layers with the two
devices. The mean FAZ area in the superficial
retinal layer was 0.55 ± 0.16 mm2 vs 0.31 ±
0.08 mm2 in the Spectralis and Optovue devices,
respectively (Figure 1, P < 0.001). Similarly, the
mean FAZ area in the deep retinal layer was
significantly greater in the Spectralis as compared
to the Optovue images (0.36 ± 0.13 mm2 vs 0.26
± 0.08 mm2, P <0.001). The mean FAZ area of
the full retina was also significantly larger with
the Spectralis as compared to the Optovue device
(0.36 ± 0.10 mm2 vs. 0.26 ± 0.07 mm2, P <0.001).

With both devices, the mean FAZ area was
significantly larger in the superficial retinal layer
(both P-values < 0.001, Figure 1). None of the eyes
had smaller FAZ area in the superficial retina as
compared to the deep retina.

Bland–Altman plots (Figure 2) demonstrated
lack of agreement between the two devices
measuring the FAZ area in superficial, deep, and
full retinal slabs.

DISCUSSION

In this study, the FAZ measurements were
significantly larger in the superficial retina
as compared to deep retinal layers, and both
measurements were significantly greater using
the Spectralis as compared to the Optovue.
The OCTA provides volumetric data for different
retinal layers. Each commercially available OCTA
device uses a distinct built-in software for image

processing and retinal layer segmentation. The
details of segmentation algorithms are proprietary
to manufacturers and are not publicly available.
Limited studies have reported the comparisons
of measurements using different devices.[18] The
methodology and results are conflicting between
these studies.

In the current study, the FAZ area was
manually determined using the ImageJ in
the images captured by two spectral domain
devices, Spectralis and Optovue, after automated
segmentation of superficial and deep retinal
layers. An excellent agreement between the
independent graders was observed for both
devices. Consequently, manual calculation of
the FAZ area was a reliable and valid method.
This is consistent with the results of previous
studies reporting FAZ measurements in a single
device.[12, 17, 19–25]

In our study, the mean FAZ area measured
with Optovue was similar to previous studies
(Table 2).[12, 17, 19–25] However, Spectralis OCTA
measurements were larger than previously
reported values, particularly in the SVC. We
believe that the discrepancy between our results
and previous reports is a result of the recent
software update and changes in segmentation
reference lines. Previous versions of Spectralis
segmented the SCP from the ILM to the outer
boundary of IPL, and the DCP from the outer
boundary of the IPL to the outer boundary of
the OPL. In recent software upgrades, the slabs
are segmented differently as mentioned in the
Methods section. Similar to our study, Mihailovic
et al[24] showed that the FAZ area is larger in
Spectralis images as compared to the Optovue
device.

The mean FAZ area measured by Optovue
was smaller than Spectralis for all measured
capillary plexuses. Spaide et al[15] indicated that
none of the automated segmentations by three
different OCTA devices (Cirrus 5000 [Carl Zeiss
Meditec], RTVue XR Avanti [Optovue], and Triton
DRI OCT [Topcon Medical Systems]) correlated
with histological sections. Similarly, Magrath
et al[20] reported significant variability in FAZ
measurements between Optovue and Zeiss Cirrus
HD-OCT 5000 (Carl Zeiss Meditec) devices,
possibly due to different slab segmentation and
dissimilarities in image spatial resolution.

In contrast to previous reports, the mean FAZ
area at the SCP was significantly larger than

JOURNAL OF OPHTHALMIC AND VISION RESEARCH VOLUME 15, ISSUE 4, OCTOBER-DECEMBER 2020 519



Fovea Avascular Zone in Two OCTA Devices; Anvari et al

Figure 1. Foveal avascular zone area measurements of one eye using Optovue and Heidelberg Spectralis devices at superficial,
deep, and full retinal slabs.

Figure 2. The Bland-Altman plots showing lack of agreement between Spectralis and Optovue devices in measuring FAZ area at
A) superficial, B) deep and C) full retinal slabs.
sFAZ, superficial foveal avascular zone; dFAZ, deep foveal avascular zone; rFAZ, foveal avascular zone in full retinal slab; LoA,
Limit of Agreement

the DCP in the current study. OCTA instruments
only approximately measure the SCP and DCP in
lieu of the four established capillary plexuses on
histological examinations,[17] and current limitations
of spatial resolution of different OCTA instruments
may explain the observed discrepancies. Rommel
et al[16] revealed that the FAZ area may be different
in manual segmentation of retinal layers as
compared to those obtained with automated
segmentations. They found that in Canon device,
the mean FAZ area was greater at the SCP than
DCP on manual slab segmentation simulating
histologic sections.[16] We used the updated

versions of the Optovue and Spectralis (Figure 3),
the new segmentation algorithms may be closer to
histologic descriptions of retinal capillary plexuses,
as described by Spaides et al.[15]

Our study showed the importance of taking into
account the instrument type as well as the software
version in assessing quantitative metrics obtained
from OCTA devices. This is particularly important
when assessing the progression of a disease or
response to an intervention using the FAZ area on
OCTA images.

We demonstrated the lack of agreement
between Spectralis and Optovue in assessing

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Fovea Avascular Zone in Two OCTA Devices; Anvari et al

Table 1. Comparison of the mean foveal avascular zone area at different capillary plexuses between the Spectralis and Optovue
devices

Slab Optovue Spectralis P-value*

Superficial capillary plexus (mm2) 0.31 ± 0.08 0.55 ± 0.16 P < 0.001
Deep capillary plexus (mm2) 0.26 ± 0.08 0.36 ± 0.13 P < 0.001
Full retina (mm2) 0.26 ± 0.07 0.36 ± 0.10 P < 0.001
∗Paired t-test

Table 2. Foveal avascular zone area measured in previous studies using Optovue or Spectralis devices

Authors Superficial (mm2) Deep (mm2) Subjects OCTA device

Shahlaee et al, 2015[12] 0.27 ± 0.101 0.34 ± 0.116 17 healthy subjects Optovue, version
2014.2.0.93

Samara et al, 2015[19] 0.266 ± 0.097 0.495 ± 0.227 70 eyes from 67
healthy subjects

Optovue, version
2014.2.0.13

Magrath et al, 2016[20] 0.2855 0.3465 50 eyes in 25
healthy volunteers

Optovue,
2014.2.0.65

Pilotto et al, 2018[21] 0.30 ± 0.08 0.35 ± 0.08 59 normal eyes Spectralis
unspecified
version

Coscas et al, 2016[22] 0.28 ± 0.1 0.37 ± 0.12 135 eyes of 70
subjects

Optovue, version
2015.100.0.35

Ghassemi et al, 2017[23] 0.27 0.35 224 eyes of 112
volunteers

Optovue, version
2016.1.0.23-beta

Corvi et al, 2017[17] Spectralis: 0.2408
Optovue: 0.2211

Spectralis: 0.3178
Optovue: 0.2619

36 eyes Optovue, version
2016.1.0.2

Spectralis, version
SP 6.7a

Mihailovic et al, 2018[24] 0.329 0.335 24 normal eyes Spectralis,
unspecified
version

Falavarjani et al, 2018[26] 0.32 ± 0.11 0.50 ± 0.13 70 eyes of 70
healthy subjects

Optovue, version
2016.1.0.26

FAZ area at different retinal layers. The average
bias was larger when evaluating FAZ in the
superficial retinal layers. Similarly, Mihailovic
and colleagues[24] showed slight but significant
differences among Canon, Heidelberg, and
Optovue in measuring the FAZ area.

One of the limitations of this study was
relatively small sample size. Restricting the
investigation to just two OCTA devices was another
limitation. Larger studies are required to establish
the relationship between FAZ measurements
using different OCTA devices. In addition, the
segmentation algorithm was different in the
two devices. Further studies are warranted to
demonstrate the repeatability of the measurements
after manually changing segmentation boundaries
to make them similar in different devices.

In conclusion, OCTA measurements are reliable
for evaluation of FAZ area in various retinal slabs,
however, commercially available devices may yield
different values depending on their segmentation
algorithms. Therefore, caution should be exercised
in comparing measurements acquired by different
OCTA devices.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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Fovea Avascular Zone in Two OCTA Devices; Anvari et al

Figure 3. Comparison of foveal vascular zone area of one eye using two different software versions of the Optovue device.
SCP, superficial capillary plexus; DCP, deep capillary plexus

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https://doi.org/10.1371/journal.pone.0206045
https://doi.org/10.4103/jovr.jovr_173_17
https://doi.org/10.4103/jovr.jovr_173_17
https://doi.org/10.4103/jovr.jovr_173_17
https://doi.org/10.4103/jovr.jovr_173_17